Catalytic Steam Gasification of Biomass: Catalysts, Thermodynamics

Jun 8, 2011 - That same year, he was awarded the Medal of Research and Development from the Professional Engineers of Ontario. Hugo de Lasa ... Citati...
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Catalytic Steam Gasification of Biomass: Catalysts, Thermodynamics and Kinetics Hugo de Lasa,* Enrique Salaices, Jahirul Mazumder, and Rahima Lucky Chemical Reactor Engineering Centre, The University of Western Ontario, London, Ontario, Canada N6A5B8

CONTENTS 1. Introduction 2. Steam Gasification of Biomass 2.1. Types of Biomass 2.2. Chemical Characteristic of Plant Biomass 2.3. Physical Characteristic of Plant Biomass 2.3.1. Biomass Size 2.3.2. Biomass Structure 2.4. Chemistry of Gasification 2.5. Design of Gasifiers 2.5.1. Fixed-Bed Gasifiers 2.5.2. Fluidized-Bed Gasifiers 2.5.3. Advantages/Disadvantages of the Different Gasifying Reactors 2.6. Gasifier Operating Conditions 2.6.1. Equivalence Ratio 2.6.2. Operating Temperature 2.6.3. Operating Pressure 2.6.4. Gasifying Agents 2.6.5. Residence Time 2.7. Advantages and Technical Challenges for Biomass Gasifiers 3. Catalysts for Steam Gasification of Biomass 3.1. Dolomite, Olivine, and Alkali Metal-Based Catalysts 3.2. Nickel-Based Catalysts 3.2.1. Catalyst Deactivation 3.2.2. Effect of Catalyst Support and Dopants 4. Thermodynamics of Steam Gasification of Biomass 4.1. Nonstoichiometric Approach 4.2. Thermodynamic Modeling of Biomass Gasification 4.3. CREC Thermodynamic Biomass Gasification Model 4.3.1. Equilibrium Constants 4.3.2. Distribution of Product Species 4.4. Thermodynamic Analysis of Coke Formation 4.5. Gas-Phase Reactions: At Thermodynamic Equilibrium or Kinetically Limited? 4.6. Optimizing Gasifier Operating 5. Kinetic Studies of Catalytic Steam Gasification of Biomass r 2011 American Chemical Society

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5.1. 5.2. 5.3. 5.4.

Kinetic Modeling Time Scale Analysis Kinetic Models at Particle Scale Intrinsic Kinetics for Biomass Gasification: The CREC “Additive Effect” Model 6. Conclusions and Future Prospects Author Information Biographies Acknowledgment Notation Greek Symbols Acronyms References

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1. INTRODUCTION Biomass, a hydrocarbon material mainly consisting of carbon, hydrogen, oxygen, nitrogen, and minerals, is considered an ideal renewable resource given its abundance, its lower sulfur content, and its CO2-neutral emissions. In catalytic biomass gasification, zero net emissions of carbon dioxide can be achieved because the carbon dioxide released from biomass is quantitatively recycled back into plants via photosynthesis.1 Biomass gasification produces very low levels of particulates, as well as very little amounts of NOx and SOx when compared with fossil fuels.2 Moreover, biomass can be used as a source to produce various chemical species.3 Biomass from plants was the first fuel used by humans to meet their energy demands. In the 19th century, the discovery of fossil fuels helped to industrialize the world and improve standards of living. It displaced, however, quite considerably the use of biomass as a fuel. In addition, the production and consumption of fossil fuels have caused environmental damage by increasing the CO2 concentration in the atmosphere.4 As the world’s accessible oil reservoirs are gradually depleted, it is important to develop suitable long-term strategies based on the utilization of renewable fuel that will gradually substitute the declining fossil fuel production. In this respect, plant biomass is the only currently sustainable source of organic carbon and biofuels.5 The 220 billion dry tons of annual available biomass (ca. 4500 EJ of energy content) potentially represents the world’s largest sustainable energy source.6 As a result, it is becoming one of the most important renewable energy sources in our planet’s immediate future. Received: January 12, 2011 Published: June 08, 2011 5404

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Chemical Reviews Biochemical and thermochemical biomass conversion processes are utilized to produce heat and electricity, as well as various chemical feedstocks. The thermochemical processes that have been studied to date are combustion, pyrolysis, and gasification. Among them, gasification of biomass is one of the most economical and efficient technologies for biomass conversion to energy and an attractive alternative for the thermal conversion of solid waste. Gasification technology, primarily wood gasifiers, was used to power cars in the early 1920s in Sweden, as a result of the general lack of indigenous petroleum resources and the abundance of biomass resources in the form of wood. Extensive studies were undertaken during the 19391945 period to further refine the design of the wood gasifiers, gas cleaning, cooling systems, and gas turbines to optimize their performance on wood waste.7 In the 1970s and 1980s, about 40 worldwide companies offered to build biomass gasification plants to produce heat and electricity.5 Nowadays, the flexibility of gasification technology, combined with the various uses of syngas, allows biomass gasification to be integrated with several industrial processes, as well as with power generation systems.2,5 The chemical efficiency of gasification exceeds 70%. This allows overall electrical efficiencies of over 40%, using high-pressure gasification coupled with fuel cell generation. Moreover, the use of wastebiomass energy production systems in rural communities is very appealing.8 In recent years, biomass steam gasification has become an area of growing interest because it produces a synthesis gas with relatively higher hydrogen content. This syngas could be used for industrial applications, both for highly efficient electricity production and as a feedstock for chemical synthesis. Catalytic steam gasification of biomass in fluidized beds is a promising approach given its (i) rapid biomass heating, (ii) effective heat and mass transfer between reacting phases, and (iii) uniform gasifier reaction temperature. Moreover, fluidized beds tolerate wide variations in fuel quality as well as broad particle size distributions. However, a serious issue for the broad implementation of the biomass gasification technology is the generation of unwanted char and tars. Char or biochar is a solid carbonaceous residue. Tar is a complex mixture of condensable hydrocarbons, which includes single-ring to five-ring aromatic compounds along with other oxygen-containing hydrocarbons species. Additional information about tar is provided in Table 4. Tar can condense in the gasifier pipe outlets and in particulate filters, which leads to blockages and filter clogging. Tar causes further downstream problems and clogs fuel lines and injectors in internal combustion engines. According to Milne et al.,9 “tar is the most cumbersome and problematic parameter in any gasification commercialization effort”. For commercial applications, tar components have to be limited to 1000 °C. According to Devi et al.,10 the catalytic reforming of tars into gaseous products is an effective method for tar removal, avoiding costly tar disposal. In this respect, Ni-based catalysts can contribute given their ability to convert tar and their water gas shift activity as well as their capacity in reducing nitrogen-containing compounds such as ammonia. However, several deactivation mechanisms occur with nickelbased catalysts including poisoning with sulfur, chlorine, and alkali metals, sintering of Ni particles, and coke formation. Under these conditions, Ni-based catalysts deactivate rapidly due to coke.11 While coke can be removed by combustion, coke removal can lead, if not carefully performed, to poor catalyst activity, selectivity, and limited catalyst life. Coke deposition can also be minimized through the use of excess steam with respect to the one required by gasification stoichiometry.12 In practice, this increases the overall energy costs for gasification plant operation. Furthermore, there is a remaining solid inorganic residue left after gasification that is designated as ash. It is highly desirable to keep the operating temperature of the gasifier below 700 °C, to prevent ash agglomeration. Ash frequently contains CaO, K2O, P2O5, MgO, SiO2, SO3, and Na2O that can sinter, agglomerate, and deposit on surfaces and contribute to erosion and corrosion of the gasifier.13 Furthermore, alkaline metals react readily in the gasifier with silica-forming silicates or with sulfur-producing alkali sulfates, leaving a sticky deposit and in many instances causing bed sintering and defluidization.1416 Synthesis gas, produced from biomass, is required to be cleaned from trace amounts of H2S, COS, CS2, HCl, NH3, and HCN at the ppb level. To accomplish this without a negative impact on process thermal efficiency, the synthesis gas has to be cleaned at high temperatures.17 In this regard, Leibold et al.18 has considered a high temperaturehigh pressure cleaning process with the syngas produced being suitable for FischerTropsch synthesis. Catalytic biomass gasification is a complex reaction process that includes numerous chemical reactions such as pyrolysis, steam gasification, and water gas shift reaction.19 Extensive research has been made to develop stable and highly active catalysts for biomass gasification producing high-quality synthesis gas and/or hydrogen.10,2026 However, designing an optimum catalyst for steam gasification requires additional insights into gasification kinetics and reaction mechanisms to predict the endreaction product composition distribution. Furthermore, long-life catalysts for biomass steam gasification are required for large-scale processes to operate in the 700800 °C range, yielding H2/CO ratios of ∼1 or even higher, suitable for the alternative manufacturing of fuels such as ethanol and biodiesel.27 To date, a significant volume of research on thermodynamic models provides valuable tools to predict an approximate product composition under various gasification operating conditions. Although these models provide satisfactory predictions of the H2/CO ratio, in most cases the observed synthesis gas compositions deviate from chemical equilibrium predictions.19 Specifically, experimental methane composition, a very critical parameter that is used to define the heating value of the synthesis gas, deviates considerably from most of the model-predicted thermodynamic values. The main reasons for this deviation are due to some inadequate assumptions adopted such as the following: (i) assumed equilibrium conditions for some key 5405

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Chemical Reviews reaction steps, (ii) char and tar accumulation being considered as solid carbon, and (iii) ash being treated as an inert species. It is well acknowledged that, in an actual process, various gasification reactions cannot reach chemical equilibrium and that the abovementioned deviations are affected by the different reactivities of char/tar. Furthermore, even the ash can have positive catalytic activity in the pyrolysis step, which may influence the synthesis gas composition. Therefore, reactor design and operation call for suitable phenomenologically based reaction kinetics adaptable to various biomass feedstocks and suitable for unit scale-up. It is our view that a critical and up-to-date review of gasification reaction mechanisms and kinetics, as is provided in this paper, gives valuable information and future direction for reaction engineering and process design in the context of biomass catalytic gasification. Several books, book chapters, and a significant volume of review articles have been published in the technical literature focusing on different issues such as (i) tar removal, (ii) catalyst for biomass gasification, (iii) hot gas cleaning, and (iv) characteristics of biomass. These are all important factors in biomass gasification technology. However, and in spite of the significance of all this, there is no comprehensive review on biomass catalytic gasification with emphasis on thermodynamics, kinetics, and catalyst properties as well as feedstock characteristics. We believe that, in all these respects, this is a timely contribution. We anticipate that this review will promote research and development efforts, scale-up of the gasification process, and large-scale implementation of catalytic steam gasification of biomass. In this article, research contributions are reported according to the following sections: • In section 2, we review the steam gasification process with main emphasis given to the chemical and physical characteristic of plant biomass, gasifier designs, and operating conditions. This is done to provide a general background and allow the reader to understand the influence of operating variables on biomass gasification. • In section 3, we give an account of catalysts used for steam gasification. Main emphasis is given to the nickel catalyst and to the new catalytic materials being investigated by CRECUWO researchers. • In section 4, we discuss thermodynamics studies of steam gasification of biomass, and particularly we describe a new thermodynamic model recently formulated by the CRECUWO research team. Emphasis is placed on the general applicability of this thermodynamic equilibrium model to different biomass feedstocks and for reaction times larger than 20 s. • In section 5, we review biomass gasification reaction engineering. We also elaborate on the very important advances of the CREC-UWO researchers on kinetic modeling using an “algebraic addition” of reaction rates of the main catalytic reactions contributing to biomass gasification. • In section 6, we provide concluding remarks and future prospects for catalytic gasification technology.

2. STEAM GASIFICATION OF BIOMASS There are different biomass conversion processes utilized to produce heat and electricity, as well as to convert biomass into various chemical species. Thermochemical transformation or gasification of cellulose or lignocellulose into synthesis gas

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(COþ H2) is possible above 700 °C in the presence of controlled amounts of oxygen. On the other hand, if lignocelluloses are heated in the absence of oxygen, then a mixture of gases, bio-oils, tars, and char are generated. This pyrolysis process requires a high energy input. There is another method for the conversion of cellulose using hot and compressed sub- and/or supercritical water. Supercritical water gasification of biomass is a technology especially recommended for wet biomass where no biomass drying is required.28,29 In addition to the interesting prospects of forming less tar and char, supercritical water gasification can produce a significant fraction of extra hydrogen originating in the water rather than in the biomass.30,31 Supercritical water displays high acidity, and thus, the reactor materials are prone to corrode. As a result, the process is penalized for its high capital costs, requiring a large monetary investment. The hydrolysis of cellulose with mineral acids or enzymes has been used for a quite a number of years already. However, its commercial use is hindered by problems associated by the following: (i) degradation of monomers, (ii) corrosion risk, (iii) handling and storage of acids/enzymes, (iv) generation of neutralized waste, and (v) separation of the product.14,32 In recent years, steam biomass gasification has become an area of growing interest because it produces a gaseous fuel with relatively high hydrogen content. Synthesis gas can be used for industrial applications, including efficient electricity production, and as a feedstock for chemical synthesis. Theoretically, almost all kinds of biomass with moisture content in the 530 wt % range can be gasified. However, it is known that feedstock (biomass) properties, such as (i) specific surface area, (ii) size, (iii) shape, (iv) moisture content, (v) volatile matter, and (vi) carbon content, all affect gasification. Other variables that also significantly influence gasification are (a) the gasifier configuration, (b) the specific gasification process conditions used, and (c) the gasifying agent. A detailed review of the many biomass conversion processes shows that no individual process is without drawbacks.33 Thus, it is critical to find an effective and efficient biomass conversion technology to utilize this renewable energy resource. It is in this respect essential to understand the gasification chemistry to determine the influence of each variable on gasification. Furthermore, one must also study the full feedstock to establish both the contribution by the individual lump components and the possible interactive effects of various biomass constituents. In the following section, the several variables affecting the gasification process, such as (i) chemical and physical biomass characteristics, (ii) operating conditions, and (iii) gasifier design, are reviewed. 2.1. Types of Biomass

Biomass is organic matter derived from plants and waste. Researchers characterize the various types of biomass by dividing them into four major categories:3 (i) Energy crops. Energy crops are those grown especially for the purpose of producing energy encompassing shortrotation or energy plantations: they comprise herbaceous energy crops, woody energy crops, industrial crops, agricultural crops, and aquatic crops. Typical examples are eucalyptus, willows, poplars, assorghum, sugar cane, artichokes, soya beans, sunflowers, cotton, and rapeseed such as Salix Viminalis, Miscanthus X Giganteus (MXG), and Andropogon Gerardi. Energy crops are suitable to be used 5406

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(ii) Agricultural residues and waste. Large quantities of agricultural plant residues are produced annually worldwide and are vastly underutilized. The most common agricultural residue is the rice husk, which makes up 25% of rice by mass. Other plant residues include sugar cane fiber (bagasse), coconut husks and shells, groundnut (peanut) shells, and straw. Included in agricultural residue is waste, such as animal manure (e.g., from cattle, chicken, and pigs). Because of the low heating value of the syngas produced using animal manure, manure is not technically feasible as the only gasifier fuel and other potential options have to be considered. For instance, cow dung can be used as a supplementary fuel blended with a conventional woody biomass, like sawdust.35 Another type of waste from domestic or industrial sources is refuse-derived fuel (RDF). This is a combustible material consisting mainly of plant matter but may also include some waste plastics from garbage. RDF may be used in the raw and untreated variety, in the partially processed form, or in the fully processed form of pellets. (iii) Forestry waste and residues. These wastes and residues include mill wood waste, logging residue, and tree and

in combustion, pyrolysis, and gasification for the production of biofuels, synthesis gas, and hydrogen.34 Table 1. Ultimate Analyses of a Diverse Variety of Biomass Compositions ultimate analysis biomass jute stick

C 47.18

H

O

N

CxHyOz S

x

y

z

ref

8.36 44.10 0.36

1.0 2.11 0.70 46

glucose heterotrophic

76.22 11.61 11.24 0.93

1.0 2.00 1.00 1.0 1.81 0.11 46

potato starch

42.50

6.40 50.80 0.00 0.000 1.0 1.79 0.90 47

poplar wood sawdust 42.70

6.20 50.90 0.10 0.100 1.0 1.73 0.89 47

pine sawdust

50.26

6.72 42.66 0.16 0.200 1.0 1.59 0.64 48

legume straw

43.30

5.62 50.35 0.61 0.120 1.0 1.55 0.87 48

rice straw

36.90

4.70 32.50 0.30 0.060 1.0 1.52 0.66 49

softwood bark

77.56

8.69 13.30 0.59

pine waste wood

51.60 55.11

4.90 42.60 0.90 1.0 1.13 0.62 50 6.01 37.99 0.86 0.030 1.0 1.30 0.52 51

coal

75.80

4.40 16.70 1.89 1.220 1.0 0.69 0.17 52

1.0 1.34 0.13 46

Figure 1. (a1) Chemical linkages in a cellulose polymer, (a2) cellulose surrogate model (glucose) used in gasification experiments; (b1) chemical linkages in a lignin polymer, (b2) lignin surrogate model (2-methoxy-4-methyl phenol) used in gasification experiments. Adapted with permission from data reported by Salaices in ref 27. 5407

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shrub residues. Fuels from wood (wood fuel and charcoal) are derived from natural forests, natural woodlands, and forestry plantations. Wood fuel is the principal source for small-scale industrial energy in the rural areas of developing countries. However, reforestation will be required to meet future energy demands as the world population grows. A possible predominant biomass-derived fuel is from wood-processing industries. The utilization of this residue for energy production at or near its source has the advantage of avoiding expensive transporting costs. Domestic wood fuels are sourced principally from land clearing and logging residues. (iv) Industrial and municipal wastes. This waste encompasses municipal solid waste (MSW), sewage sludge, and industry waste.36 Municipal solid wastes and industrial residues such as black liquor from wood pulping also represent potential biomass feedstocks.37 They pose, however, major problems in gasification technology. Straw and municipal solid wastes may form large amounts of ash deposits in the furnace or convective sections of utility boilers.38 In this respect, cost-effective methods for the management of remaining ash are actively being studied.39 A significant volume of published articles on gasification using various sources of biomass confirmed that thermal degradation kinetics, reactivity, and product characteristics all change with the type of biomass used.40 The amount and type of char and tar from gasification appear to be composed of different chemical species. These chemical species are a function of the feedstock used and of the different cracking pathways.41 For example, Kosstrin42 proved through experiments that the highest yield of tar was 35% for wood, ∼60% for paper, and only 30% for sawdust.43 This was attributed to the fact that gasification products are affected by Table 2. Typical Compositions of Biomass1 ASTM biomass

E-1821-96

E-1821-96

E-1721-95

E-1758-95

E-1758-95

T-250

cellulose

hemicellulose

Lignin (wt %)

ash (wt %)

16.628.6

0.49.7

(wt %) hardwood

36.450.3

E-1755-95

(wt %) 12.723.2

biomass chemical composition, as well as moisture content and type of alkali content.44 2.2. Chemical Characteristic of Plant Biomass

Every biomass type has carbon, hydrogen, and oxygen as major chemical constitutive elements. These element fractions can be quantified with the ultimate analysis. The ultimate analyses of 13 biomass feedstocks are reported in Table 1. Ultimate analyses are reported using the CxHyOz formula where x, y, and z represent the elemental fractions of C, H, and O, respectively. On this basis, it can be predicted that given biomass low hydrogen and high oxygen contents, all biomasses have a low calorific value, which is a main disadvantage for direct biomass utilization as an energy source.45 One can also establish that the oxygen available in biomass only allows 6587 wt % of the carbon to be converted into CO, while the remaining 13 35 wt % of the carbon requires additional oxygen supply. Moreover, the products of biomass gasification also depend on the various amounts of inorganic materials that yield ash during the gasification. The ash formed has a significant influence on the gasification itself.53 To fully describe biomass characteristics, it is customary to provide, in addition to the ultimate analysis (percentage of carbon, hydrogen, and oxygen), the proximate analysis. This analysis includes the content of moisture, volatile matter, fixed carbon, and ash. Woody plant species are typically characterized by slow growth and are composed of tightly bound fibers, giving a hard external surface, whereas herbaceous plants are usually perennial, with more loosely bound fibers, indicating a lower proportion of lignin, which binds together the cellulosic fibers. Biomass is mainly formed of hemicellulose, cellulose, lignin, and ash (Table 2). The relative proportions of cellulose and lignin are two of the determining factors in identifying the suitability of plant species for subsequent processing as energy crops. Cellulose is a glucose polymer, consisting of linear chains of glucopyranose units, with an average molecular weight of around 100 000 kg/kmol. Hemicellulose is a mixture of polysaccharides, composed almost entirely of sugars such as glucose, mannose, xylose, and arabinose with an average molecular weight of 30 000 kg/kmol. In contrast to cellulose, hemicellulose is a heterogeneous branched

Figure 2. (a) Pyrolysis of biomass in a nitrogen atmosphere and (b) biomass conversion in an air atmosphere.56 5408

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Table 3. Tar Maturation Scheme5

species

400 °C

500 °C

600 °C

700 °C

800 °C

900 °C

mixed oxygenates

phenolic ethers

alkyl phenols

heterocyclic ethers

polynuclear aromatic hydrocarbons

larger polynuclear aromatics

Table 4. Chemical Components in Biomass Tars5 conventional flash pyrolysis (450500 °C)

high-temperature flash pyrolysis (600650 °C)

conventional steam gasification (700800 °C)

high-temperature steam gasification (9001000 °C)

acids

benzenes

naphthalenes

naphthalene

aldehydes

phenols

acenaphthylenes

acenaphthylene

ketones

catechols

fluorenes

phenanthrene

furans

naphthalenes

phenanthrenes

fluoranthene

alcohols

biphenyls

benzaldehydes

pyrene

complex oxygenates

phenanthrenes benzofurans

phenols naphthofurans

acephenanthrylene benzanthracenes

phenols

benzaldehydes

benzanthracenes

benzopyrenes

guaiacols

polyaromatic hydrocarbons

syringols complex phenols

Figure 3. Composition of hydrocarbon products from steam gasification of biomass surrogate (2-methoxy-4-methylphenol) at 700 °C, with an S/B ratio of 0.4 and 30 s of contact time.27 Codes in the chart: 1, methane; 2, ethylene; 3, ethane; 4, 1,3-pentadiene; 5, 2-butene, 2-methyl; 6, 1,3-pentadiene; 7, 1,3-cyclopentadiene; 8, 1,3-butadiene, 2, 3-dimethyl; 9, 1,3-cyclopentadiene; 10, benzene; 11, toluene; 12, ethylbenzene; 13, o-xylene; 14, p-xylene; 15, benzene, 1-ethyl-3-methyl; 16, phenol; 17, benzene, 1-ethenyl-2-methyl; 18, benzocyclobutene-1(2H)one; 19, indene; 20, phenol, 3-methyl; 21, 2-propenal, 3-phenyl; 22, naphthalene; 23, phenol, 2-ethyl-5-methyl; 24, naphthalene, 2-methyl; 25, naphthalene, 1-methyl; 26, naphthalene, 1,7-dimethyl; 27, naphthalene, 2,3-dimethyl; 28, 1,10 -biphenyl, 3-methyl; 29, 1-naphthalenol; 30, 2-naphthalenol; 31, 7-methyl-1-naphthol; 32, 9H-fluoren-9-ol; 33, naphtho[2,1-b]furan, 1,2-dimethyl; 34, anthracene; 35, phenanthrene.

polysaccharide that binds tightly and noncovalently to the surface of each cellulose microfibril. Lignin can be regarded as a group of amorphous, high molecular weight, chemically related compounds. The building blocks of lignin are believed to be a three carbon chain attached to rings of six carbon atoms, called phenylpropanes. Both woody and herbaceous plant species have specific growing conditions, based on the soil type, moisture, nutrient balances, and sunlight, all of which determine their suitability and productive growth rates in specific geographic locations.54 Biomass hemicellulose, cellulose, and lignin constituents decompose in the temperature ranges of 225325, 305375, and 250500 °C, respectively.55 A schematic representation of

the biomass pyrolysis under inert gas atmosphere and biomass air atmosphere is reported in Figure 2.56 Elliott57 reviewed the composition of biomass pyrolysis products and gasifier tars from various processes. Tables 3 and 4 show the expected transition from primary products to phenolic compounds to aromatic hydrocarbons, as a function of process temperature. Furthermore, Figure 3 reports the composition of products derived from atmospheric-pressure gasification of biomass at 700 °C, with an S/B ratio of 0.4 and with 30 s contact time in a CREC riser simulator. A biomass surrogate (2-methoxy-4methylphenol) is used in this process. The figure shows the aromatics and oxygenate species fractions contained in the tar (C6þ) fraction.27 The variation of constituent fractions in biomass gives products with a different heating value. Furthermore, and taking into account that lignin gasification produces more hydrogen than other components of the biomass, pretreatments that improve lignin content are important.58 Regarding biomass constituents, there is still controversy regarding the possible interactions among the different components of biomass during gasification.43,53,5961 It was observed in this respect that the formation of water-soluble tars occurs mainly in the early stages of pure cellulose gasification. This is in contrast with the lower water-soluble tar yields obtained with full biomass. In this respect, significant interactions such as celluloselignin were observed in pyrolysis. It appears that lignin inhibits the thermal polymerization of levoglucosan as well as enhances the formation of low molecular weight products from cellulose. This, in turn, reduces the yields of char and the secondary char formation from lignin. As a result, this improves the production of some lignin-derived species such as guaiacol, 4-methylguaiacol, and 4-vinylguaiacol. Comparatively weak interactions were also observed in cellulosehemicellulose pyrolysis.62 Furthermore, the yields of water-insoluble tars formed from pure cellulose are substantially less than from full biomass. This shows that there are interactions between lignin, cellulose, and hemicellulose biomass components during gasification. 5409

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Figure 4. Van Krevelen’s diagram showing the various H/C ratios and O/C ratios for different feedstocks. Adapted with permission from ref 54. Copyright 2002.

Biomass pyrolysis also yields a solid product residue, the char. T-Raman spectroscopy has been used to analyze the structure of chars and biochars. In the case of biochars, it has been shown that they are highly heterogeneous and disordered structures. Biochar gasification can be significantly influenced by the inherent alkali and alkaline soil metallic contents (AAEM). In fact, the AAEM present in raw biochars can act as a catalyst accelerating some gasification steps.63 This AAEM effect, however, appears to have little influence on the structural properties of biochars, such as pore surface area.64 Mineral matter and mineral concentration are dependent on genotype as well as on the location in which the plants are grown. However, biomass mineral concentration cannot always be easily related to the mineral soil content.65 While biomass is converted, ash can be traced to the biomass mineral matter content. Ash offers challenges to biomass conversion including sintering, agglomeration, deposition, erosion, and corrosion. These are the main obstacles to economical and viable applications of biomass gasification technologies.66 Furthermore, it is well documented that ash contributes as a catalyst. Ash may at the same time reduce the H2 yields in the air gasifier.50,66,67 Raveendran et al.68 have studied the influence of mineral matter in pyrolysis by demineralizing the biomass and then impregnating it with salts. This study has reported the following: (1) Demineralized biomass yields higher tar fractions. (2) Demineralized biomass increases char yields, as in the case of coir pith, groundnut shell, and rice husk. (3) Demineralized corn cob and wood reduces char yields. (4) Demineralized rice husk yields higher char yield than coir pith and groundnut shell. One should notice that, with temperature variations, the amount of ash emissions may also vary. In the 100500 °C range, a small fraction of the ash may be emitted. Above 600 °C, ash releases can increase sharply. In fluidized bed gasifiers, however, ash emissions may be significantly reduced due to particle particle collisions and, as a result, enhanced ash agglomeration. Moreover, ashes, which are continuously produced and normally disposed of in landfills, may have an adverse effect on the environment. Small ash particles may contribute to both air pollution and groundwater pollution through metal leaching. Ash can be used as a pozzolanic material mixed with concrete or cement. This reduces both the consumption of concrete and cement and landfill area requirements. This in turn can help decrease the environmental impact caused by concrete and cement manufacturing involving both high energy consumption and CO2 emissions.69

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Moisture is an important constituent in biomass. Moisture content should be determined on an ash-free basis. Although water is needed for a suitable gasification,70,71 a moisture content that is too high means that more air for combustion is needed to sustain the gasifier temperature. Although higher gasification temperatures may lead to better carbon conversion and lower tar emissions, these temperatures may also give a synthesis gas with lower heating value and, as a result, lower synthesis gas utilization efficiency. Biomass gasification can be studied in principle, using as a starting point the components of biomass.72 There is, however, as stated above, evidence of interactions among the components of the biofeedstock while being gasified. These observations are based on thermogravimetric analysis (TGA) and differential thermogravimetric analysis (DTG) obtained at different heating rates for full biomass, pure wood, pure cellulose, pure hemicellulose, and pure lignin. Thermograms for all these cases display different temperatures at maximum weight losses (Tm) as follows: (1) For pure hemicellulose, pure cellulose, and pure lignin, single Tm values were observed. (2) For wood, two Tm values were recorded. These two Tm's were close to the ones for pure cellulose and pure hemicellulose. Gasification of biomass with varying elemental compositions of organic matter can be assessed in a Van Krevelen’s diagram73 in terms of hydrogen/carbon (H/C) and oxygen/carbon (O/C) ratios as described in Figure 4. Wood, cellulose, and lignin are represented in this diagram together with coal and peat. It can be observed, in this respect, that exergy losses in wood gasification (O/C ratio ≈ 0.6) are larger than those for coal (O/C ratio ≈ 0.2). Thus, for a fuel with an O/C ratio below 0.4 and a lower heating value (LHV) of >23 MJ/kg, a gasification temperature of 927 °C is recommended. On the other hand, for a fuel with O/C ratio below 0.3 and a LHV of 26 MJ/kg or more, a 1227 °C gasification temperature is preferred. As a result of this, it could thus be attractive to modify the properties of oxygenated biofuels prior to gasification as follows: (i) by separation of wood into its components with gasification of the lignin performed at a later process step and (ii) by thermal pretreatment, and/or biomass mixing with coal, to enhance the heating value of the solid fed to the gasifier.74 2.3. Physical Characteristic of Plant Biomass

Several pretreatments are performed in biomass gasification facilities in an effort to precondition the feedstock such as (i) drying, (ii) size reduction, (iii) size fractionation, and (iv) leaching with water. One should notice, however, that the degree of pretreatment of the biomass feedstock is dependent on both the fuel and the gasification technology used.75,76 2.3.1. Biomass Size. Since pyrolysis and gasification of biomass are thermochemical processes, the temperature and rates of particle heating have pronounced effects on the weight loss of biomass. To achieve this, the smaller the biomass size, the better is the fluidparticle heat transfer. If the temperature is uniform throughout the particle, this yields a more controlled gasification. Moreover, whenever the intrinsic kinetics controls the overall gasification process, gasification rates increase exponentially with temperature following Arrhenius’ rate law. One has to be aware that, given that biomass particle size reduction is quite an intensive energy process, particle size should not be smaller than required. Maa and Bailie77 have 5410

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Chemical Reviews shown that, in the pyrolysis of cellulose, the intrinsic reaction rate controls the overall gasification for particles smaller than 0.2 cm. For particles in the 0.26 cm size range, both heat transfer and intrinsic reaction rate have an influence on the gasification. For particles larger than 6 cm, the gasification rate becomes fully controlled by heat transfer.53 Erlich et al.78 studied the effects of (i) classification, (ii) source, (iii) size, and (iv) shape of biomass during slow pyrolysis and steam gasification. This research group reported that the biomass pellet size has an impact on the gasification rate but only very slightly on pyrolysis rate. The larger the pellet, the slower the gasification becomes. Moreover, a recent report showed that char combustion reactivity can be increased in larger biomass particles (1.55.18 mm), increasing the alkaline metal content species concentration.79 2.3.2. Biomass Structure. Biomass is frequently a highly porous material with a very high surface area. Diffusion of the reactants and products in many instances takes place under nonrestricted molecular transport. Furthermore, when the biomass is highly porous, uniform temperature can be achieved in biomass pellets resulting in homogeneous gasification in all portions of biomass, yielding uniform composition of product gases. On the other hand, when biomass is less porous, the temperature may vary from a maximum temperature at the pellet exterior to a minimum value at the center. In those cases, gasification on biomass exterior surfaces may dominate, with biomass external surface shrinking throughout the gasification. Because of the nonuniformity of temperature, drying, pyrolysis, and gasification, these processes may take place concurrently, yielding nonuniform composition of gases.53 2.4. Chemistry of Gasification

Gasification is a thermochemical conversion process of solid biomass into a gas-phase mixture of carbon monoxide (CO), hydrogen (H2), carbon dioxide (CO2), methane (CH4), organic vapors, tars (benzene and other aromatic hydrocarbons), water vapor, hydrogen sulfide (H2S), residual solids, and other trace species (HCN, NH3, and HCl). The specific fractions of the various species obtained may depend on process conditions and on the environment (inert, steam) prevailing during gasification. Other inorganic materials present in biomass such as Si, Al, Ti, Fe, Ca, Mg, Na, K, P, S, and Cl may also be converted to gaseous species. Upon heating, the biomass dries up, until it reaches 120 °C. Volatiles are produced until it reaches 350 °C, and the resulting char is gasified above 350 °C. Therefore, it is customary to classify the entire gasifier process into three steps: drying, devolatilization, and gasification.55,80 Gasification itself is a combination of pyrolysis and oxidation reactions. Chemical species are heated up to 500900 °C in the presence of air, steam, CO2, or other components. Heat to drive the process is generated either outside the unit or in the same unit via exothermic biomass combustion. Evans and Milne81 observed three major reaction regimes during the gasification process identified as primary, secondary, and tertiary regimes. During the primary stage below 500 °C of gasification, solid biomass forms gaseous H2O, CO2, oxygenated vapor species, and primary oxygenated liquids. The primary oxygenated vapors and liquids include cellulose-derived molecules (such as levoglucosan, hydroxyacetaldehyde), their analogous hemicellulose-derived products, and lignin-derived methoxyphenols. No chemical interactions were observed among

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the organic compounds during primary pyrolysis reactions, which are substantially free of secondary gas-phase cracking products. Primary pyrolysis vapors are of rather low molecular weight, representing monomers and fragments of monomers. However, the aromatization process starts at 350 °C and continues at higher temperatures.82 During the secondary stage, which takes place from 700 to 850 °C, the primary vapors and liquids form gaseous olefins, CO, CO2, H2, H2O, and condensable oils such as phenols and aromatics. The composition of tars formed during this phase is reported in Table 3. Gases and remaining tars undergo other secondary reactions such as water gas shift, methanation, steam reforming, and cracking. However, these reactions in which catalysts are not present are generally too slow. The only exception is the water gas shift reaction.83 Further heating of evolved chemical species occurs from 850 to 1000 °C, resulting in a reaction phase where secondary products form, consisting of CO, CO2, H2, H2O, and polynuclear aromatics (PNA). These compounds include methyl derivatives of aromatics such as methyl acenaphthylene, methyl naphthalene, toluene, and indene. Some other products such as benzene, naphthalene, acenaphthylene, anthracene, phenanthrene, and pyrene condense to form a liquid tar phase.83 According to Evans et al.,84 the composition of the tars changes as the temperatures increases in the following order: mixed oxygenates f phenolic ethers f alkyl phenolics f heterocyclic ethers f polyaromatic hydrocarbons f larger polyaromatic hydrocarbons.5 However, an analysis of the high-temperature tar derived from cellulose showed levoglucosan to be a primary component.11 The time of the gasification has significant effects on tar conversion. Longer vapor residence times at pyrolysis temperatures yields more secondary vapor-phase cracking leading to additional gases, water, formic acid, acetic acid, and other low-molecularweight products.9,85 Soot and coke are formed during these secondary and tertiary processes. Coke forms from thermolysis of liquids and organic vapors. The homogeneous nucleation of the intermediate chemical species, produced at high temperature, yields soot in the gas phase. During gasification, the inorganic components of the biomass are usually converted into ash, which is removed from the bottom of the gasifier (bottom ash), or into fly ash, which leaves with the product gas. The composition of the ash includes CaO, K2O, P2O5, MgO, SiO2, SO3, Na2O, and residual carbon. Volatile halogen elements and alkali elements are mainly found in wet scrubber ash and in fly ash, whereas Si, Ni, Pb, Zn, Cr, Cd, K, S, Mn, and Cu elements are typically contained in the ash separator exit, enriched with heavy metals.13 Among biomass formed products, char retains the morphology of the original lignocelluloses. Char is formed through crosslinking reactions via condensation and water loss86 with slow pyrolysis yielding more char.87 The char yield decreases rapidly with increasing temperature until 400 °C is reached. As the temperature increases, the char becomes progressively more aromatic and high in carbon. This is due to the removal of hydroxyl, aliphatic CH bonds and carbonyl and olefinic CdC groups. The release of volatile matter opens spaces in the char pore structure at the higher gasification temperatures. Higher temperatures may also lead to char softening, melting, and fusion. The shrinkage of the carbon structure may take place above 500 °C, which is concurrent with the aromatization process.82 Char that is formed from the initial pyrolysis and from secondary 5411

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Figure 5. Schematic of (a) updraft and (b) down draft gasifier. Adapted from75.

tar reactions continues to pyrolyze and react with steam (i.e., the carbon/steam reaction), producing additional permanent gases. 2.5. Design of Gasifiers

Gasifiers can be divided into two principal types: fixed beds and fluidized beds, with variations within each type. A third type, the entrained suspension gasifier, has been developed for the gasification of finely divided coal particles (10 MW) fixedbed gasifiers have lost a part of their industrial market appeal. Yet, small-scale (